KR100190972B1 - Stabilization apparatus and method for inverter stand - Google Patents

Abstract

The present invention relates to a stabilization device and method of the inverter stand, the constant voltage unit 100 for supplying a constant voltage to the set, the key input unit 200 consisting of various keys including a touch sensor for setting the operation mode of the set, and a lamp Oscillation supplied to the lamp driver 400 by receiving the microprocessor 300 and the frequency conversion data output from the microprocessor 300 to control the overall operation of the set based on the illuminance or the key input of (L). A frequency converter 400 for converting the frequency, a lamp driver 500 for adjusting the level of operating power supplied to the lamp L by receiving the oscillation frequency output from the frequency converter 400, and a set of In the inverter stand having a display unit 600 for displaying the operation state, the temperature sensing unit 700 for detecting the internal temperature of the inverter stand case 850, and the air intake The cooling fan motor driver 800 and the microprocessor 300 driving the respective fan motors 810 output a drive signal to the cooling fan motor driver 800 when the internal temperature is higher than a predetermined temperature. Various elements constituted can be induced to operate normally, and their life can be extended.

Description

Stabilizer and method of inverter stand.

The present invention relates to an inverter stand, and more particularly, to an inverter stand stabilization apparatus and method for lowering the internal temperature by sucking the outside air when the internal temperature of the inverter stand is higher than a predetermined set temperature.

1 and 2, a general inverter stand includes a bridge diode, a zener diode, a capacitor, and the like, and provides a constant voltage unit 101 for supplying a constant voltage to a set. And a key input unit 102 including keys for setting the operation mode of the set, including a touch sensor installed on a support of the inverter stand, and frequency conversion for adjusting the illuminance of the lamp by receiving a key input. It is composed of a microprocessor 103 for outputting data, a plurality of capacitors and resistors for converting the oscillation IC and its oscillation frequency, and receiving the frequency conversion data output from the microprocessor 103 to the lamp driver 104. The frequency converter 104 converts the supplied oscillation frequency and the oscillation frequency output from the frequency converter 104 to perform a switching operation. Is composed of a lamp driver 105 having a field effect transistor, a transformer for controlling the level of the operating power supplied to the lamp L in association with the field effect transistor, a display unit 106 for displaying the operating state of the set, and the like. have.

When the main power is supplied by the touch sensor of the key input unit 102, the inverter determines the time constant of the frequency converter 104 having a capacitor and a resistance by frequency conversion data output from the microprocessor 103. The IC oscillates an oscillation frequency of approximately 50 KHz to 90 KHz and applies it to the transformer primary side of the lamp driver 105. Then, the plurality of field effect transistors are alternately operated by the voltage generated on the secondary side of the transformer to adjust the operating power supplied to the lamp L. At this time, the lamp L is turned on as the power supplied from the constant voltage unit 101 is charged and discharged through the transformer formed at the front end of the lamp L, through the self resistance of the lamp, and a loop formed by a plurality of field effect transistors. .

Subsequently, when the illuminance sensed by the illuminance sensor 109 is converted, in order to adjust the brightness of the light generated by the lamp L, the oscillation IC causes the oscillation IC to convert the time constant of the corresponding frequency constant. Try to oscillate the frequency. Then, the oscillation frequency of the lamp driver 105 may be adjusted to adjust the illuminance of the lamp L. FIG. Here, as the oscillation frequency supplied from the frequency converter 104 to the lamp driver 105 increases, the current supplied to the lamp L decreases, so that the light of the lamp L becomes weak.

Since most of the inverter stand lights in the dark space or at night, the light switch, that is, the key is composed of a touch sensor so that the lamp of the inverter stand can be smoothly lit. The touch sensor is activated when the human body touches while the main power is being input. The current operating state of the inverter stand is then switched. That is, when the touch sensor is operated by the human body while the lamp of the inverter stand is turned off, the lamp is turned on, whereas when the touch sensor is operated by the human body while the lamp of the inverter stand is turned on, the lamp is turned off. In addition, the microprocessor 103 may drive a buzzer (generally using a piezo buzzer) that is not shown when the touch sensor is operated or a key is pressed to check the operation state of the touch sensor or another key input. Output buzzer sound. Accordingly, the operation state of the touch sensor or the key input state of the key input unit 102 can be checked.

In such an inverter stand, the brightness of the lamp L continues to be kept high or the internal temperature of the inverter stand case rises when an abnormality occurs in the control means for driving the lamp L. Accordingly, there is a drawback that various elements configured inside the case of the inverter stand malfunction or generate high heat to cause a stable accident.

The present invention devised to solve the above-mentioned drawbacks is to provide a stabilizer and a method of stabilizing the inverter stand to remove the heat generated inside the case of the inverter stand to perform a stable operation of the inverter stand. have.

To this end, the present invention for controlling the illuminance of the lamp by adjusting the operating power supplied to the lamp manually or automatically, detecting the internal temperature of the case of the inverter stand, and determining whether the internal temperature of the case is higher than the set temperature And, if the internal temperature is high, detecting the internal temperature of the case of the inverter stand while driving the cooling fan motor, determining whether the internal temperature is higher than the set temperature while driving the cooling fan motor, and if the internal temperature is high, It is characterized in that it is made to detect the internal temperature while continuing to drive and to stop the cooling fan motor when low.

1 is a block diagram showing the configuration of a typical inverter stand,

2 is a perspective view of a typical inverter stand,

3 is a block diagram showing the configuration of an inverter stand according to the present invention;

4 is a partial cutaway front view of the inverter stand according to the present invention;

5 is a flowchart illustrating an operating state of the inverter stand according to the present invention.

Explanation of symbols on the main parts of the drawings

100: constant voltage unit 200: key input unit

300: microprocessor 400: frequency converter

500: lamp driving unit 600: display unit

700: temperature detection unit 800: cooling fan motor drive unit

810: cooling fan motor 820: space

830 device 840 PCB

850: Case 860: Outlet

As shown in FIG. 3, the present invention provides a constant voltage unit 100 for supplying a constant voltage to a set, a key input unit 200 including various keys including a touch sensor for setting an operation mode of the set, and a lamp L. The microprocessor 300 which controls the overall operation of the set based on the illuminance or the key input, and the frequency conversion data output from the microprocessor 300 are applied to convert the oscillation frequency supplied to the lamp driver 400. Display the operating state of the set and the lamp driver 500 for adjusting the level of the operating power supplied to the lamp (L) by receiving the frequency converter 400, the oscillation frequency output from the frequency converter 400 In the inverter stand having a display unit 600, the temperature sensing unit 700 for detecting the internal temperature of the inverter stand case 850, and the cooling fan motor for driving the cooling fan motor 810 to suck air Fan motor driving unit 800 and the microprocessor 300 consists of the internal temperature to output a drive signal to the motor driving the cooling fan 800 at greater than a predetermined temperature.

Here, the cooling fan motor 810 is installed at the lower end of the case 850, as shown in Figure 4, the discharge port 860 for discharging the internal air is formed at the upper end of the case 850.

5 is a flowchart illustrating an operating state of the inverter stand according to the present invention. In the case of adjusting the illuminance of the lamp by adjusting the operating power supplied to the lamp manually or automatically, the internal temperature of the case of the inverter stand is adjusted. Sensing the case, determining whether the internal temperature of the case is higher than the set temperature, detecting the internal temperature of the case of the inverter stand while driving the cooling fan motor if the internal temperature is high, and setting the internal temperature while driving the cooling fan motor. Determining whether the temperature is higher than the temperature, and if the internal temperature is high while continuing to drive the cooling fan motor to detect the internal temperature, and stops the cooling fan motor if the temperature is low.

The inverter stand configured as described above maintains the lighting state and the microprocessor 300 senses the internal temperature of the case 850 by the temperature data output from the temperature detecting unit 700 (which includes the temperature detecting sensor) (S1). ). In order to stabilize the internal temperature of the case 850, it is determined whether the internal temperature is higher than a predetermined set temperature (S2). As a result, when the case internal temperature is lower than the set temperature, the lamp is controlled by adjusting the operating power supplied to the lamp L by the illuminance data detected by the illuminance sensor in the manual or automatic mode as described in the conventional inverter stand. Adjust the brightness of (L).

However, when the internal temperature is higher than the set temperature, the microprocessor 300 outputs a driving signal to the display unit 600 to inform that the internal temperature is detected to be higher than the set temperature (S3). That is, the case 850 informs that the internal temperature is unstable. Subsequently, a driving signal is output to the cooling fan motor driver 800 to drive the cooling fan motor 810 (S4). Accordingly, since the air sucked by the cooling fan motor 810 is discharged to the discharge port 860 via the space 820 where the device 830 of the PCB 840 is located, the heat generated by the device 830 can be eliminated. have. Of course, the microprocessor 300 checks the change state of the internal temperature of the case 850 by receiving the temperature data output from the temperature sensing unit 700 while controlling the operation (S5).

Preferably, when the internal temperature detected by the temperature sensing unit 700 is continuously detected for a predetermined time in a state higher than the set temperature, the microprocessor 300 outputs a driving signal to the cooling fan motor driving unit 800; At the same time, the lamp L is turned off by cutting off the frequency conversion data output to the frequency converter 400. This may prevent the internal temperature from rising further.

While operating the cooling fan motor 810, the microprocessor 300 continuously determines whether the case internal temperature is higher than the set temperature (S6). As a result, if the internal temperature is continuously high, the above operations (S3), S4, and S5 are repeatedly performed, but if the internal temperature is lower than the set temperature, the display stand 600 is operated to stabilize the inverter stand. While S7 is notified, the cooling fan motor 810 is stopped by blocking the driving signal output to the cooling fan motor driver 800. Accordingly, it is possible to prevent the internal temperature of the case 850 including the various elements 830 from rising above the set temperature. Of course, when it is determined that the internal temperature is lower than the set temperature, the microprocessor 300 repeatedly performs the above operation by the internal temperature detected by the temperature sensing unit 700 while adjusting the brightness of the lamp L.

The present invention detects the internal temperature of the case of the inverter stand and if the internal temperature of the case is higher than the set temperature, while driving the cooling fan motor continuously detects the internal temperature of the case of the inverter stand, and then while driving the cooling fan motor to remove the internal temperature. Re-determine whether the internal temperature is higher than the set temperature, and if the internal temperature is high, continue to drive the cooling fan motor and detect the internal temperature, but if it is low, stop the cooling fan motor. Can also lead to prolongation of their lifetime.

In addition, it is possible to prevent safety accidents due to heat generated by abnormal operation of various elements of the inverter stand.

Claims (5)

A constant voltage unit 100 for supplying a constant voltage to the set, a key input unit 200 composed of various keys including a touch sensor for setting an operation mode of the set, and a light intensity or key input of the lamp L The microprocessor 300 for controlling the overall operation, the frequency converter 400 for converting the oscillation frequency supplied to the lamp driver 400 receives the frequency conversion data output from the microprocessor 300, and the frequency Inverter stand having a lamp driver 500 for adjusting the level of the operating power supplied to the lamp L by receiving the oscillation frequency output from the converter 400, and a display unit 600 for displaying the operation state of the set To A temperature sensing unit 700 for sensing an internal temperature of the inverter stand case 850; A cooling fan motor driver 800 driving the cooling fan motor 810 for sucking air; The microprocessor 300 is a stabilization device of the inverter stand, characterized in that made to output a drive signal to the cooling fan motor drive unit 800 when the internal temperature is above a predetermined temperature. The inverter of claim 1, wherein the cooling fan motor 810 is installed at a lower end of the case 850, and an outlet 860 for discharging internal air is formed at an upper end of the case 850. Stabilizer of the stand. In adjusting the illuminance of the lamp L by manually or automatically adjusting the operating power supplied to the lamp L, Sensing a temperature inside the case 850; Determining whether the internal temperature is higher than the set temperature; Detecting an internal temperature of the case 850 while driving the cooling fan motor 810 when the internal temperature is high; Determining whether an internal temperature is higher than a set temperature while driving the cooling fan motor 810; When the internal temperature is high, the drive stand stabilization method characterized in that it is made to detect the internal temperature while continuing to drive the cooling fan motor 810 and to stop the cooling fan motor (810). 4. The method of claim 3, wherein the cooling fan motor 810 outputs the operation / stop state to the display unit 600. 4. The inverter stand according to claim 3, wherein the cooling fan motor 810 is operated and the lamp L is turned off while the internal temperature is continuously maintained for a predetermined time higher than the set temperature. Stabilization method.